Draft:Weil Conjectures - Abelian Surfaces

Draft article not currently submitted for review. This is a draft Articles for creation (AfC) submission. It is not currently pending review. While there are no deadlines, abandoned drafts may be deleted after six months. To edit the draft click on the "Edit" tab at the top of the window. To be accepted, a draft should: Show the subject qualifies for a Wikipedia article by using multiple sources that meet four criteria. The sources should be (1) reliable (2) secondary (3) independent of the subject (4) talk about the subject in some depth. For some topics, there are alternative criteria. Be written from a neutral point of view Respect copyright and do not plagiarize. Do not copy-paste. It is strongly discouraged to write about yourself, your business or employer. If you do so, you must declare it. Where to get help If you need help editing or submitting your draft, please ask us a question at the AfC Help Desk or get live help from experienced editors. These venues are only for help with editing and the submission process, not to get reviews. If you need feedback on your draft, or if the review is taking a lot of time, you can try asking for help on the talk page of a relevant WikiProject. Some WikiProjects are more active than others so a speedy reply is not guaranteed. How to improve a draft Wikipedia:Contributing to Wikipedia – a basic overview on how to edit Wikipedia. Help:Wikitext – how to use the markup Help:Referencing for beginners – how to include references Wikipedia:Article development – how to develop your article Wikipedia:Writing better articles – how to improve your article Wikipedia:Verifiability – make sure your article includes reliable third-party sources You can also browse Wikipedia:Featured articles and Wikipedia:Good articles to find examples of Wikipedia's best writing on topics similar to your proposed article. Improving your odds of a speedy review To improve your odds of a faster review, tag your draft with relevant WikiProject tags using the button below. This will let reviewers know a new draft has been submitted in their area of interest. For instance, if you wrote about a female astronomer, you would want to add the Biography, Astronomy, and Women scientists tags. Add tags to your draft Editor resources Find sources: Google (books · news · scholar · free images · WP refs) · FENS · JSTOR · TWL Easy tools: Citation bot (help) | Advanced: Fix bare URLs Last edited by Chrgue (talk | contribs) 38 days ago. (Update) Submit the draft for review!

Abelian surfaces

An Abelian surface is a two-dimensional Abelian variety. This is, they are projective varieties that also have the structure of a group, in a way that is compatible with the group composition and taking inverses. Elliptic curves represent one-dimensional Abelian varieties. As an example of an Abelian surface defined over a finite field, consider the Jacobian variety ${\displaystyle X:={\text{Jac}}(C/F_{41})}$ of the genus 2 curve ^[1]

${\displaystyle C/F_{41}:y^{2}+y=x^{5},}$

which was introduced in the section on hyperelliptic curves. The dimension of ${\displaystyle X}$ equals the genus of ${\displaystyle C}$, so ${\displaystyle n=2}$. There are algebraic integers ${\displaystyle \alpha _{1},\ldots ,\alpha _{4}}$ such that^[2]

1. the polynomial ${\displaystyle P(x)=\prod _{j=1}^{4}(x-\alpha _{j})}$ has coefficients in ${\displaystyle \mathbb {Z} }$;
2. ${\displaystyle M_{k}:=|{\text{Jac}}(C/F_{41^{k}})|=\prod _{j=1}^{4}(1-\alpha _{j}^{k})}$ for all ${\displaystyle k\geq 1}$; and
3. ${\displaystyle |\alpha _{j}|={\sqrt {41}}}$ for ${\displaystyle j=1,\ldots ,4}$.

The zeta-function of ${\displaystyle X}$ is given by

${\displaystyle \zeta (X,s)=\prod _{i=0}^{4}P_{i}(q^{-s})^{(-1)^{i+1}}={\frac {P_{1}(T)\cdot P_{3}(T)}{P_{0}(T)\cdot P_{2}(T)\cdot P_{4}(T)}},}$

where ${\displaystyle q=41}$, ${\displaystyle T=q^{-s}\,{\stackrel {\rm {def}}{=}}\,{\text{exp}}(-s\cdot {\text{log}}(41))}$, and ${\displaystyle s}$ represents the complex variable of the zeta-function. The Weil polynomials ${\displaystyle P_{i}(T)}$ have the following specific form (Kahn 2020):

${\displaystyle P_{i}(T)=\prod _{1\leq j_{1}<j_{2}<\ldots <j_{i-1}<j_{i}\leq 4}(1-\alpha _{j_{1}}\cdot \ldots \cdot \alpha _{j_{i}}T)}$

for ${\displaystyle i=0,1,\ldots ,4}$, and

${\displaystyle P_{1}(T)=\prod _{j=1}^{4}(1-\alpha _{j}T)=1-9\cdot T+71\cdot T^{2}-9\cdot 41\cdot T^{3}+41^{2}\cdot T^{4}}$

is the same for the curve ${\displaystyle C}$ (see section above) and its Jacobian variety ${\displaystyle X}$. This is, the inverse roots of ${\displaystyle P_{i}(T)}$ are the products ${\displaystyle \alpha _{j_{1}}\cdot \ldots \cdot \alpha _{j_{i}}}$ that consist of ${\displaystyle i}$ many, different inverse roots of ${\displaystyle P_{1}(T)}$. Hence, all coefficients of the polynomials ${\displaystyle P_{i}(T)}$ can be expressed as polynomial functions of the parameters ${\displaystyle c_{1}=-9}$, ${\displaystyle c_{2}=71}$ and ${\displaystyle q=41}$ appearing in ${\displaystyle P_{1}(T)=1+c_{1}T+c_{2}T^{2}+qc_{1}T^{3}+q^{2}T^{4}.}$ Calculating these polynomial functions for the coefficients of the ${\displaystyle P_{i}(T)}$ shows that

${\displaystyle {\begin{alignedat}{2}P_{0}(T)&=1-T\\P_{1}(T)&=1-3^{2}\cdot T+71\cdot T^{2}-3^{2}\cdot 41\cdot T^{3}+41^{2}\cdot T^{4}\\P_{2}(T)&=(1-41\cdot T)^{2}\cdot (1+11\cdot T+3\cdot 7\cdot 41\cdot T^{2}+11\cdot 41^{2}\cdot T^{3}+41^{4}\cdot T^{4})\\P_{3}(T)&=1-3^{2}\cdot 41\cdot T+71\cdot 41^{2}\cdot T^{2}-3^{2}\cdot 41^{4}\cdot T^{3}+41^{6}\cdot T^{4}\\P_{4}(T)&=1-41^{2}\cdot T\end{alignedat}}}$

Polynomial ${\displaystyle P_{1}}$ allows for calculating the numbers of elements of the Jacobian variety ${\displaystyle {\text{Jac}}(C)}$ over the finite field ${\displaystyle F_{41}}$ and its field extension ${\displaystyle F_{41^{2}}}$:^[3][4]

${\displaystyle {\begin{alignedat}{2}M_{1}&\;{\overset {\underset {\mathrm {def} }{}}{=}}\;|{\text{Jac}}(C/F_{41})|=P_{1}(1)=\prod _{j=1}^{4}[1-\alpha _{j}T]_{T=1}\\&=[1-9\cdot T+71\cdot T^{2}-9\cdot 41\cdot T^{3}+41^{2}\cdot T^{4}]_{T=1}=1-9+71-9\cdot 41+41^{2}=1375=5^{3}\cdot 11{\text{, and}}\\M_{2}&\;{\overset {\underset {\mathrm {def} }{}}{=}}\;|{\text{Jac}}(C/F_{41^{2}})|=\prod _{j=1}^{4}[1-\alpha _{j}^{2}T]_{T=1}\\&=[1+61\cdot T+3\cdot 587\cdot T^{2}+61\cdot 41^{2}\cdot T^{3}+41^{4}\cdot T^{4}]_{T=1}=2930125=5^{3}\cdot 11\cdot 2131.\end{alignedat}}}$

The inverses ${\displaystyle \alpha _{i,j}}$ of the zeros of ${\displaystyle P_{i}(T)}$ do have the expected absolute value of ${\displaystyle 41^{i/2}}$ (Riemann hypothesis). Moreover, the maps ${\displaystyle \alpha _{i,j}\longmapsto 41^{2}/\alpha _{i,j},}$ ${\displaystyle j=1,\ldots ,\deg P_{i},}$ correlate the inverses of the zeros of ${\displaystyle P_{i}(T)}$ and the inverses of the zeros of ${\displaystyle P_{4-i}(T)}$. A non-singular, complex, projective, algebraic variety ${\displaystyle Y}$ with good reduction at the prime 41 to ${\displaystyle X={\text{Jac}}(C/F_{41})}$ must necessarily have Betti numbers ${\displaystyle B_{0}=B_{4}=1,B_{1}=B_{3}=4,B_{2}=6}$, since these are the degrees of the polynomials ${\displaystyle P_{i}(T).}$ The Euler characteristic ${\displaystyle E}$ of ${\displaystyle X}$ is given by the alternating sum of these degrees/Betti numbers: ${\displaystyle E=1-4+6-4+1=0}$.

By taking the logarithm of

${\displaystyle \zeta ({\text{Jac}}(C/F_{41}),s)\,=\,\exp \left(\sum _{m=1}^{\infty }{\frac {M_{m}}{m}}(41^{-s})^{m}\right)\,=\,\prod _{i=0}^{4}\,P_{i}(41^{-s})^{(-1)^{i+1}}={\frac {P_{1}(T)\cdot P_{3}(T)}{P_{0}(T)\cdot P_{2}(T)\cdot P_{4}(T)}},}$

it follows that

${\displaystyle {\begin{alignedat}{2}\sum _{m=1}^{\infty }&{\frac {M_{m}}{m}}(41^{-s})^{m}\,=\,\log \left({\frac {P_{1}(T)\cdot P_{3}(T)}{P_{0}(T)\cdot P_{2}(T)\cdot P_{4}(T)}}\right)\\&=1375\cdot T+2930125/2\cdot T^{2}+4755796375/3\cdot T^{3}+7984359145125/4\cdot T^{4}+13426146538750000/5\cdot T^{5}+O(T^{6}).\end{alignedat}}}$

Aside from the values ${\displaystyle M_{1}}$ and ${\displaystyle M_{2}}$ already known, you can read off from this Taylor series all other numbers ${\displaystyle M_{m}}$, ${\displaystyle m\in \mathbb {N} }$, of ${\displaystyle F_{41^{m}}}$-rational elements of the Jacobian variety, defined over ${\displaystyle F_{41}}$, of the curve ${\displaystyle C/F_{41}}$: for instance, ${\displaystyle M_{3}=4755796375=5^{3}\cdot 11\cdot 61\cdot 56701}$ and ${\displaystyle M_{4}=7984359145125=3^{4}\cdot 5^{3}\cdot 11\cdot 2131\cdot 33641}$. In doing so, ${\displaystyle m_{1}|m_{2}}$ always implies ${\displaystyle M_{m_{1}}|M_{m_{2}}}$ since then, ${\displaystyle {\text{Jac}}(C/F_{41^{m_{1}}})}$ is a subgroup of ${\displaystyle {\text{Jac}}(C/F_{41^{m_{2}}})}$.

References

1. LMFDB: Abelian variety isogeny class 2.41.aj_ct over F(41)
2. Chapter V, Theorem 19.1 in Milne, James (1986). "Abelian Varieties". Arithmetic Geometry. New York: Springer-Verlag. pp. 103–150. doi:10.1007/978-1-4613-8655-1. ISBN 978-1-4613-8655-1.
3. Chapter 6, Theorem 5.1 in Koblitz, Neal (1998). Algebraic Aspects of Cryptography. Springer. p. 146. ISBN 3-540-63446-0.
4. LMFDB: Abelian variety isogeny class 2.41.aj_ct over F(41)

• Kahn, Bruno (2020), "The zeta function of an abelian variety", Zeta and L-Functions of Varieties and Motives, London Mathematical Society Lecture Note Series, Cambridge: Cambridge University Press, pp. 52–53, doi:10.1017/9781108691536, ISBN 978-1-108-70339-0
• Koblitz, Neal (1998), "Elliptic and Hyperelliptic Cryptosystems", Algebraic Aspects of Cryptography, Algorithms and Computation in Mathematics, vol. 3, Berlin, Heidelberg: Springer-Verlag, pp. 146–147, doi:10.1007/978-3-662-03642-6, ISBN 978-3-662-03642-6
• Milne, James (1986), "Abelian Varieties", Arithmetic Geometry, New York: Springer-Verlag, pp. 103–150, doi:10.1007/978-1-4613-8655-1, ISBN 978-1-4613-8655-1